Data processing method and device for LED televison, and LED television

ABSTRACT

A data processing method and device for a Light emitting diode (LED) Television (TV), and an LED TV are disclosed, the data processing device includes: a signal processing chip configured to perform mode conversion on a received TV signal so as to obtain a first video signal of a preset mode; and a video processing chip connected to the signal processing chip and configured to perform clock synchronization processing on the first video signal so as to obtain a second video signal and output the second video signal to an LED display. The problem in the prior art that an LED TV can only display a TV signal of a single mode is solved, thereby achieving the effect that the LED TV can display videos of various modes and various formats.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a National Phase Application of PCT InternationalApplication No. PCT/CN2014/083167, International Filing Date Jul. 28,2014, claiming priority of Chinese Patent Application No.201410165980.0, filed Apr. 23, 2014, the entirety of which is herebyincorporated by reference.

FIELD OF THE INVENTION

The disclosure relates to the field of Light Emitting Diodes (LED),particularly to a data processing method and device for an LEDTelevision (TV) and an LED TV.

BACKGROUND OF THE INVENTION

An existing self-luminous LED TV is a display device product emergedwith recent development of LED display technology, and a high definitionself-luminous LED display screen, which is able to implement functionsincluding an extremely short distance, a high physical resolution and soon and has strong color performance and obviously superior grey scaleand contrast, is absolutely applicable to displaying signals and imagesof various forms of video interfaces. However, a video interface of theexisting LED TV is in a single form, and a received TV signal isdisplayed on the LED display screen directly, thereby resulting in pooreffect of a display image as well as poor visual effect of a user.

Specifically, an LED display technology in the past, which mainlyemerged in a form of a display screen, generally applies an access formof a single video interface (such as a Video Graphics Array (VGA) and aDigital Visual Interface (DVI)), and displays an accessed TV signal onthe display screen directly without any processing. In other words, theexisting LED TV only serves as a display screen in most cases, but doesnot serve as a TV and an image is displayed in poor quality.

At present, there is no effective solution yet for the problem in theprior art that an LED can only display a TV signal of a single mode.

SUMMARY OF THE INVENTION

There is no effective solution yet for the problem in the prior art thatan LED can only display a TV signal of a single mode. Therefore, themajor purpose of the disclosure is to provide a data processing methodand device for an LED TV and an LED TV so as to solve the problem above.

A data processing device for an LED TV is provided according to anaspect of the embodiments of the disclosure so as to achieve the purposeabove. The data processing device includes: a signal processing chipconfigured to perform mode conversion on a received TV signal so as toobtain a first video signal of a preset mode; and a video processingchip connected with the signal processing chip and configured to performclock synchronization processing on the first video signal so as toobtain a second video signal and output the second video signal to anLED display.

Further, the signal processing chip transmits the first video signal tothe video processing chip through a low voltage differential interface,wherein the low voltage differential interface is configured to dividethe first video signal into a first low voltage differential videostream and a second low voltage differential video stream according tothe resolution of a video, and transmit the first low voltagedifferential video stream and the second low voltage differential videostream to the video processing chip, wherein the first low voltagedifferential video stream includes two differential data streams.

Further, the video processing chip includes: a decoder, connected withthe signal processing chip and configured to decode the first lowvoltage differential video stream so as to obtain two video signals, anddecode the second low voltage differential video stream so as to obtaina third video signal; a clock processor, connected with the decoder andconfigured to perform clock synchronization processing on the two videosignals and the third video signal so as to obtain the second videosignal.

Further, the clock processor includes: a video combiner, connected withthe decoder and configured to combine the two video signals into afourth video signal; the clock processor is configured to perform clocksynchronization processing on the third video signal and the fourthvideo signal so as to obtain the second video signal.

Further, the video combiner includes: two line caches, wherein the twoline caches are connected with the decoder and video streams of two datachannels of the two video signals are inputted into respectivecorresponding line caches respectively; a first data reader, connectedwith the two line caches and configured to perform a data readingoperation on the two line caches according to a clock frequency ofdoubling so as to obtain the fourth video signal.

Further, the video processing chip further includes: a video outputport, connected with the signal processing chip and configured to dividethe second video signal into a preset number of sub-videos, and outputthe sub-videos to a display unit corresponding to the LED display so asto display the sub-videos.

Further, the data processing device further includes: a control chip,configured to send an established preset coordinate to the video outputport; the video output port is configured determine to output thesub-videos to the corresponding display unit according to the presetcoordinate.

Further, the video output port includes: a frame memory, configured tostore the second video signal, wherein the frame memory includes apreset number of sub-ports; a second reader, connected with the framememory and configured to read video data from the sub-ports in a pollingmanner according to a preset reading rule; a cache, configured cacheread video data of each path and perform clock domain switching on thevideo data of each path so as to obtain the preset number of sub-videos;an output interface, connected with the cache and configured to outputthe preset number of sub-videos by means of time division multiplexing.

An LED TV is provided according to an aspect of the embodiments of thedisclosure to achieve the purpose above. The LED TV includes the dataprocessing device.

A data processing method for an LED TV is provided according to anaspect of the embodiments of the disclosure to achieve the purposeabove. The data processing method includes that mode conversion isperformed on a received TV signal so as to obtain a first video signalof a preset mode; clock synchronization processing is performed on thefirst video signal so as to obtain a second video signal; the secondvideo signal is divided into a preset number of sub-videos; and thesub-videos are outputted to a corresponding display unit of an LEDdisplay so as to display the sub-videos.

A data processing device for an LED TV is provided according to anaspect of the embodiments of the disclosure to achieve the purposeabove. The data processing device includes: a converting module,configured to perform mode conversion on a received TV signal so as toobtain a first video signal of a preset mode; a clock processing module,configured to perform clock synchronization processing on the firstvideo signal so as to obtain a second video signal; a dividing module,configured to divide the second video signal into a preset number ofsub-videos; and an output module, configured to output the sub-videos toa corresponding display unit of an LED display so as to display thesub-videos.

By means of the disclosure, a signal processing chip converts a receivedTV signal into a video signal of a preset mode, and a video processingchip processes and outputs the video signal to an LED display, therebysolving the problem in the prior art that an LED TV can only display aTV signal of a single mode and achieving the effect that the LED TV candisplay videos of various modes and various formats.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings illustrated here are used for providingfurther understanding to the disclosure and constitute a part of theapplication. The exemplary embodiments of the disclosure andillustration thereof are used for explaining the disclosure, instead ofconstituting improper limitation to the disclosure. In the accompanyingdrawings:

FIG. 1 is a structural diagram of a data processing device for an LED TVaccording to an embodiment of the disclosure;

FIG. 2 is a structural diagram of an optional data processing device foran LED TV according to an embodiment of the disclosure;

FIG. 3 is a sequence chart of obtaining a fourth video signal accordingto an embodiment of the disclosure;

FIG. 4 is a schematic diagram of determining an area of a display unitaccording to an embodiment of the disclosure;

FIG. 5 is a sequence chart of a method for reading data of a sub-videoaccording to an embodiment of the disclosure;

FIG. 6 is a flowchart of a data processing method for an LED TVaccording to an embodiment of the disclosure;

FIG. 7 is a schematic diagram of a data processing device for an LED TVaccording to an embodiment of the disclosure;

FIG. 8 is a structural diagram of a video processing ship in the dataprocessing device for the LED TV according to an embodiment of thedisclosure;

FIG. 9 is a structural diagram of a clock processor in the videoprocessing ship in the data processing device for the LED TV accordingto an embodiment of the disclosure;

FIG. 10 is a structural diagram of a video combiner in the clockprocessor in the video processing ship in the data processing device forthe LED TV according to an embodiment of the disclosure;

FIG. 11 is another structural diagram of a video processing ship in thedata processing device for the LED TV according to an embodiment of thedisclosure;

FIG. 12 is another structural diagram of a video output port in thevideo processing ship in the data processing device for the LED TVaccording to an embodiment of the disclosure.

DETAILED DESCRIPTION OF THE INVENTION

First, some nouns and terms in the description of the embodiments of thedisclosure are applicable to the following explanations:

LED: light emitting diode

Self-luminescence of an LED means that an LED device can be excited byelectricity or other energy to emit lights proactively while a liquidcrystal is only light-permeable, but does not emit lights itself.

The technical solutions in the embodiments of the disclosure will bedescribed clearly and completely hereinafter with reference to theaccompanying drawings in the embodiments of the disclosure so that thoseskilled in the art may better understand the solutions of thedisclosure. Evidently, the described embodiments are merely someembodiments rather than all embodiments of the disclosure. All otherembodiments obtained by persons of ordinary skill in the art based onthe embodiments of the disclosure without creative efforts shall belongto the protection scope of the disclosure.

It needs to be noted that the terms “first”, “second” and so on in thespecification, the claims and the accompanying drawings of thedisclosure are used for distinguishing similar objects, but are notnecessarily used for describing a specific sequence or a precedenceorder. It should be understood that data used in this way areinterchangeable in an appropriate condition, so that the embodimentsdescribed herein of the disclosure can be implemented in a sequencebesides those illustrated or described herein. In addition, the terms“include” and “have” and any other variants of them are intended tocover non-exclusive inclusion. For example, processes, methods, systems,products, or devices that include a series of steps or units are notnecessarily limited to the steps or units that are clearly listed, butmay also include other steps or units that are not clearly listed or areinherent in these processes, methods, products, or devices.

FIG. 1 is a structural diagram of a data processing device for an LED TVaccording to an embodiment of the disclosure and FIG. 2 is a structuraldiagram of an optional data processing device for an LED TV according toan embodiment of the disclosure.

As shown in FIG. 1 and FIG. 2, the device may include: a signalprocessing chip 10 configured to perform mode conversion on a receivedTV signal so as to obtain a first video signal of a preset mode; and avideo processing chip 20 connected with the signal processing chip 10and configured to perform clock synchronization processing on the firstvideo signal so as to obtain a second video signal and output the secondvideo signal to an LED display 40,

wherein the signal processing chip 10 in the embodiments above may be aTV processing chip, such as Pixelworks (a top American manufacturer ofimage display chips), Mstar (an embedded Integrated Circuit (IC) chip)and the video processing chip 20 applies a Field-Programmable Gate Array(FPGA). Specifically, the signal processing chip 10 and the videoprocessing chip 20 may be provided with a memory with a storage capacitylarger than 128 Mbit, respectively (such as frame memories: aSynchronous Dynamic Random Access Memory (SDRAM) and a Double Data RateSDRAM (DDR SDRAM). The signal processing chip performs mode conversion,image enhancement and zooming processing of the TV through an accessedTV signal (including a tuner). Besides, the signal processing chip mayalso process other accessed signals of a High-Definition MultimediaInterface (HDMI, which is a digital interface), a Universal Serial Bus(USB), a YPrPb and so on, wherein an SDRAM is a synchronous dynamicrandom access memory, a DDR is a double data rate synchronous dynamicrandom access memory, and an IC chip is an integrated circuit.

The data processing device for an LED TV in the embodiments above may bebuilt in an LED TV.

By means of the disclosure, a signal processing chip converts a receivedTV signal into a video signal of a preset mode, and a video processingchip processes and outputs the video signal to an LED display, therebysolving the problem in the prior art that an LED TV can only display aTV signal of a single mode and achieving the effect that the LED TV candisplay videos of various modes and various formats.

Specially, the mode conversion of the TV signal, video decoding anddecryption of various interfaces, image zooming, image qualityenhancement and a remote function are implemented by the TV processingchip in the embodiments above. In the embodiments above, the first videosignal obtained by the TV processing chip 10 is a video stream with afixed resolution, and such a video stream is outputted to the videoprocessing chip in a protocol form of a Low Voltage DifferentialSignaling (LVDS) (an interface of an LVDS technology). The videoprocessing chip applies a programmable logic array, and the video streaminputted by the TV processing chip is processed by a programmable logicchip.

In the embodiments above of the disclosure, the signal processing chiptransmits the first video signal to the video processing chip through alow voltage differential interface, wherein the low voltage differentialinterface is configured to divide the first video signal into a firstlow voltage differential video stream and a second low voltagedifferential video stream according to the resolution of a video, andtransmit the first low voltage differential video stream and the secondlow voltage differential video stream to the video processing chip,wherein the first low voltage differential video stream includes twodifferential data streams.

Specifically, the video stream of the first video signal processed bythe TV processing chip may be divided, according to the resolution ofthe video, into one or two groups of LVDS videos outputted to theprogrammable logic chip (i.e. the video processing chip). Generally,each group of LVDSs includes one pair of differential clocks, or threeor four pairs of differential data streams. More specifically, a videosignal with a high resolution (i.e. the first low voltage differentialvideo stream having a resolution of 1080P, for example) is generallyoutputted to the video processing chip by using two groups of LVDSswhile a video signal having a low resolution (i.e. the second lowvoltage differential video stream having a video resolution of 1366*768or below, for example) is outputted to the video processing chip byusing one group of LVDSs.

According to the embodiments above of the disclosure, as shown in FIG.8, the video processing chip 20 may include: a decoder 81, connectedwith the signal processing chip 10 and configured to decode the firstlow voltage differential video stream so as to obtain two video signals,and decode the second low voltage differential video stream so as toobtain a third video signal; a clock processor 83, connected with thedecoder 81 and configured to perform clock synchronization processing onthe two video signals and the third video signal so as to obtain thesecond video signal.

Specifically, after receiving the first low voltage differential videostream and the second low voltage differential video stream, the videoprocessing chip performs LVDS video stream decoding first, and it isnecessary to perform clock synchronization for decoded data when thedecoding is performed. In the processing process above, the videoprocessing chip needs to combine the two video signals in the first lowvoltage differential video stream after decoding a high resolution videostream (i.e. the first low voltage differential video stream)transmitted by two groups of LVDSs.

Specifically, as shown in FIG. 9, the clock processor 83 may include: avideo combiner 91, connected with the decoder 81 and configured tocombine the two video signals into a fourth video signal; the clockprocessor 83 is configured to perform clock synchronization processingon the third video signal and the fourth video signal so as to obtainthe second video signal.

According to the embodiments above of the disclosure, as shown in FIG.10, the video combiner 91 may include: two line caches 101, wherein thetwo line caches 101 are connected with the decoder 81 and video streamsof two data channels of the two video signals are inputted intorespective corresponding line caches 101 respectively; a first datareader 103, connected with the two line caches 101 and configured toperform a data reading operation on the two line caches 101 according toa clock frequency of doubling so as to obtain the fourth video signal.

As shown in FIG. 3, a processing method for combining the two videosignals (one of which is data O1, O2, O3, O4, O5, O6, O7, . . . , ofdata channel 1 and the other one is data E1, E2, E3, E4, E5, E6, E7, . .. of data channel 2) is to interleave data of two paths into data of onepath, that is, to output one piece of data of data channel 1 by means ofdata enabling, and then output one piece of data of data channel 2,thereby outputting data of the two channels alternatively and cyclicallyin turn. Since a downlink period of validity is unchanged, a pixel dataclock frequency is doubled after the combination. In the embodimentsabove of the disclosure, the two line caches are applied, the videostreams of the two data channels are inputted to into respective cachesrespectively, and a clock with a clock frequency of doubling is appliedto performing a data reading operation on the two line caches, that is,one piece of data is read from line cache 1 and another piece of data isread from the other line cache subsequently, and the data are readalternatively in turn so as to obtain the fourth video signal, as shownby O1, E1, O2, E2, O3, E3, O4, E4, O5, E5, O6, E6, O7, E7, . . . in FIG.3. It is unnecessary to combine video data of a low resolution videostream (i.e. the second low voltage differential video stream) sincethere is only one group of LVDSs.

In the embodiments above of the disclosure, as shown in FIG. 11, thevideo processing chip 20 may further include: a video output port 85,connected with the signal processing chip 10 and configured to dividethe second video signal into a preset number of sub-videos, and outputthe sub-videos to a display unit corresponding to the LED display so asto display the sub-videos.

Since an LED high-definition TV panel applies an integrated displayscreen formed by splicing display units. Data streams transmitted by thevideo processing chip to the LED display are a plurality of paralleldata streams. Specifically, it is set that n data streams are outputtedto an LED screen, and an image of a whole frame of a video image isdivided into n sub-images (the n images may be spliced into a frame of acompleted image). A matched sub-image corresponding to each video isoutputted and displayed on a corresponding display unit. In this way,the transmission rate is largely reduced in a fixed period of time,wherein n is a preset quantity and a natural number.

By means of the embodiments above, a data volume which is 1/n of anoriginal image is transmitted at a rate which is 1/n of an original onewithin a period, thereby improving the reliability of videotransmission.

According to the embodiments above of the disclosure, the dataprocessing device may further include: a control chip 30 as shown inFIG. 2, configured to send an established preset coordinate to the videooutput port; as shown in FIG. 11, the video output port 85 is configureddetermine to output the sub-videos to the corresponding display unitaccording to the preset coordinate,

wherein the control chip may be implemented by using a MicrocontrollerUnit (MCU). An LED high-definition TV processing system is implementedby a design combining the TV processing chip, the video processing chipand the control chip in the embodiments above, which can not onlyimprove the reliability of video transmission, but also improve theflexibility of video control.

A range of a specific image transmission area of each path may beconfigured and set flexibly so as to improve the flexibility of imagetransmission of each path. Specifically, a range of image transmissionis determined through the preset coordinate determined by the controlchip, so as to output a sub-video to a corresponding display unit. Forexample, an image area of transmission of each path is determined by thelocation (X,Y) of the upper left corner of the image area in the wholeframe of an image.

FIG. 4 shows that four sub-videos are outputted to the LED display, anddisplay units corresponding to the four sub-videos are read 1, area 2,area 3 and area 4 respectively, wherein an area of each display unit ina whole frame of an image is determined by using the location (x,y) ofthe upper left corner. The display locations (or display units) of area1 to area 4 may be determined by four coordinates (x1,y1), (x2,y2),(x3,y3) and (x4,y4) as shown in FIG. 4. Optionally, the locations ofrespective areas may be adjusted by setting the coordinate of X, Y (thepreset coordinate). In the embodiments above, the preset coordinate isobtained by a microprocessor (i.e. the control chip). As shown in FIG.2, command configuration may be performed on the control chip by meansof a network or a serial port so as to obtain the preset coordinate.Before outputting the sub-videos, each sub-video may be subjected toLVDS coding again and outputted to the LED screen body subsequently soas to display the sub-videos.

It needs to be further noted that, as shown in FIG. 12, the video outputport 85 may include: a frame memory 121, configured to store the secondvideo signal, wherein the frame memory 121 includes a preset number ofsub-ports; a second reader 123, connected with the frame memory 121 andconfigured to read video data from the sub-ports in a polling manneraccording to a preset reading rule; a cache 125, configured cache readvideo data of each path and perform clock domain switching on the videodata of each path so as to obtain the preset number of sub-videos; anoutput interface 127, connected with the cache 125 and configured tooutput the preset number of sub-videos by means of time divisionmultiplexing.

Specifically, video data may be stored by the frame memory first, andthen read according to the preset reading rule to as to implementconfiguration of any sub-video. As shown in FIG. 5, when reading isperformed, a period is formed by starting a process for four times (256pieces of data are read each time), that is, data of 256 pixels (256pieces of data are read each time a reading process is started) are readin a first reading of each period is data of port 0, data of 256 pixelsof port 1 are read when reading is started for a second time, data of256 pixels of port 2 are read in a third reading, and data of 256 pixelsof port 3 are read in a fourth reading. In this way, the four ports areread in a polling manner, and video data of each path are cached by acache, so as to perform clock domain switching. A writing clockfrequency of the cache is about 4 times of a reading frequency, thusread data steams are continuous. By means of the disclosure, such amultipath output method will ensure strict synchronic output of the fourvideos, thereby avoiding the problem that a feeling of an unsynchronizedtorn image is caused by displaying an image moving violently on a wholescreen due to a high LED refresh frequency.

The disclosure further provides an LED display device which may includeany data processing device in the embodiments above.

By means of the disclosure, a signal processing chip converts a receivedTV signal into a video signal of a preset mode, and a video processingchip processes and outputs the video signal to an LED display, therebysolving the problem in the prior art that an LED TV can only display aTV signal of a single mode and achieving the effect that the LED TV candisplay videos of various modes and various formats.

By means of the disclosure, an overall plan of an LED TV front end isimplemented, display processing of images is carried out and high systemreliability may be ensured for input and display of a standarddefinition image and a high definition image.

FIG. 6 is a flowchart of a data processing method for an LED TVaccording to an embodiment of the disclosure. As shown in FIG. 6, themethod may be implemented by the following steps.

Step 602: Mode conversion is performed on a received TV signal so as toobtain a first video signal of a preset mode.

Step 604: Clock synchronization processing is performed on the firstvideo signal so as to obtain a second video Signal.

Step 606: The second video signal is divided into a preset number ofsub-videos.

Step 608: The sub-videos are outputted to a corresponding display unitof an LED display so as to display the sub-videos.

By means of the disclosure, a signal processing chip converts a receivedTV signal into a video signal of a preset mode, and a video processingchip processes and outputs the video signal to an LED display, therebysolving the problem in the prior art that an LED TV can only display aTV signal of a single mode and achieving the effect that the LED TV candisplay videos of various modes and various formats. In addition,sub-videos are outputted to a display unit corresponding to the LEDdisplay and displayed after a second video signal is divided into apreset number of sub-videos, thereby not only improving the reliabilityof video transmission, but also improving the flexibility of videocontrol.

The data processing method in the embodiment above of the disclosure maybe implemented by using a video data processing method of each chip inthe foregoing method embodiments.

It needs to be noted that the steps illustrated in the flowcharts of theaccompanying drawings may be executed in a computer system, such as agroup of computer executable instructions, and although logicalsequences have been illustrated in the flowcharts, the steps asillustrated or described may be executed by a sequence different fromthe sequences described herein.

FIG. 7 is a schematic diagram of a data processing device for an LED TVaccording to an embodiment of the disclosure. As shown in FIG. 7, thedata processing device may include: a converting module 50, configuredto perform mode conversion on a received TV signal so as to obtain afirst video signal of a preset mode; a clock processing module 60,configured to perform clock synchronization processing on the firstvideo signal so as to obtain a second video signal; a dividing module70, configured to divide the second video signal into a preset number ofsub-videos; and an output module 80, configured to output the sub-videosto a corresponding display unit of an LED display so as to display thesub-videos.

By means of the disclosure, a signal processing chip converts a receivedTV signal into a video signal of a preset mode, and a video processingchip processes and outputs the video signal to an LED display, therebysolving the problem in the prior art that an LED TV can only display aTV signal of a single mode and achieving the effect that the LED TV candisplay videos of various modes and various formats. In addition,sub-videos are outputted to a display unit corresponding to the LEDdisplay and displayed after a second video signal is divided into apreset number of sub-videos, thereby not only improving the reliabilityof video transmission, but also improving the flexibility of videocontrol.

The data processing device in the embodiment above of the disclosure maybe implemented by using a video data processing method of each chip inthe foregoing method embodiments.

The disclosure may implement functions including access of a TV signal,signal enhancement, remote control and so on of a self-luminous LED TV,and process TV signals and various video signals so that the TV signalsand the video signals are applicable to a display function of an LEDhigh definition TV system.

It may be seen from the foregoing description that the disclosure hasimplemented the following technical effect.

By means of the disclosure, access, processing and display of TV signalsand various video signals of a high definition LED TV may beimplemented. In the meanwhile, video streams are combined and processedsynchronously at a video processing chip, a plurality of videosconsistent with an LED display method are configured and outputtedflexibly, and a time division multiplexing processing method of strictsynchronic output of the plurality of videos is applied, therebyimproving the display quality of an image and the reliability of signaltransmission.

Obviously, those skilled in the art should understand that the modulesor steps of the disclosure may be implemented by general-purposecomputing devices and centralized in a single computing device ordistributed over a network consisting of a plurality of computingdevices. Optionally, they may be implemented by program codes executableby a computing device, so that they may be stored in a storage deviceand executed by the computing device, or they may be implemented byrespectively fabricating them into respective integrated circuit modulesor by fabricating a plurality of modules or steps of them into a singleintegrated circuit module. By doing so, the disclosure is not limited toany specific combination of hardware and software.

The above are only preferred embodiments of the disclosure and shouldnot be used for limiting the disclosure. For those skilled in the art,the disclosure may have various modifications and changes. Anymodifications, equivalent replacements, improvements and the like withinthe spirit and principles of the disclosure shall fall within the scopeof protection of the disclosure.

What is claimed is:
 1. A data processing device for a Light emittingdiode (LED) Television (TV), comprising: a signal processing chipconfigured to perform mode conversion on a received TV signal so as toobtain a first video signal of a preset mode; and a video processingchip connected with the signal processing chip and configured to performclock synchronization processing on the first video signal so as toobtain a second video signal and output the second video signal to anLED display, wherein: the signal processing chip is configured totransmit the first video signal to the video processing chip through alow voltage differential interface, and the low voltage differentialinterface is configured to divide the first video signal into a firstlow voltage differential video stream and a second low voltagedifferential video stream according to the resolution of a video, andtransmit the first low voltage differential video stream and the secondlow voltage differential video stream to the video processing chip,wherein the first low voltage differential video stream comprises twodifferential data streams.
 2. The data processing device according toclaim 1, wherein the video processing chip comprises: a decoder,connected with the signal processing chip and configured to decode thefirst low voltage differential video stream so as to obtain two videosignals, and decode the second low voltage differential video stream soas to obtain a third video signal; a clock processor, connected with thedecoder and configured to perform clock synchronization processing onthe two video signals and the third video signal so as to obtain thesecond video signal.
 3. The data processing device according to claim 2,wherein the clock processor comprises: a video combiner, connected withthe decoder and configured to combine the two video signals into afourth video signal; the clock processor is configured to perform clocksynchronization processing on the third video signal and the fourthvideo signal so as to obtain the second video signal.
 4. The dataprocessing device according to claim 3, wherein the video combinercomprises: two line caches, wherein the two line caches are connectedwith the decoder and video streams of two data channels of the two videosignals are inputted into respective corresponding line cachesrespectively; a first data reader, connected with the two line cachesand configured to perform a data reading operation on the two linecaches according to a clock frequency of doubling so as to obtain thefourth video signal.
 5. The data processing device according to claim 1,wherein the video processing chip further comprises: a video outputport, connected with the signal processing chip and configured to dividethe second video signal into a preset number of sub-videos, and outputthe sub-videos to a display unit corresponding to the LED display so asto display the sub-videos.
 6. The data processing device according toclaim 5, wherein the data processing device further comprises: a controlchip, configured to send an established preset coordinate to the videooutput port; the video output port is configured determine to output thesub-videos to the corresponding display unit according to the presetcoordinate.
 7. The data processing device according to claim 5, whereinthe video output port comprises: a frame memory, configured to store thesecond video signal, wherein the frame memory comprises a preset numberof sub-ports; a second reader, connected with the frame memory andconfigured to read video data from the sub-ports in a polling manneraccording to a preset reading rule; a cache, configured cache read videodata of each path and perform clock domain switching on the video dataof each path so as to obtain the preset number of sub-videos; an outputinterface, connected with the cache and configured to output the presetnumber of sub-videos by means of time division multiplexing.
 8. An LEDTV, comprising the data processing device according to claim
 1. 9. Adata processing method for an LED TV, comprising: performing modeconversion on a received TV signal so as to obtain a first video signalof a preset mode; performing clock synchronization processing on thefirst video signal so as to obtain a second video signal; dividing thesecond video signal into a preset number of sub-videos; and outputtingthe sub-videos to a corresponding display unit of an LED display so asto display the sub-videos; wherein the first video signal is transmittedthrough a low voltage differential interface, wherein the low voltagedifferential interface is configured to divide the first video signalinto a first low voltage differential video stream and a second lowvoltage differential video stream according to the resolution of avideo, and transmit the first low voltage differential video stream andthe second low voltage differential video stream, wherein the first lowvoltage differential video stream comprises two differential datastreams.
 10. A data processing device for an LED TV, comprising: aconverting module, configured to perform mode conversion on a receivedTV signal so as to obtain a first video signal of a preset mode; a clockprocessing module, configured to perform clock synchronizationprocessing on the first video signal so as to obtain a second videosignal; a dividing module, configured to divide the second video signalinto a preset number of sub-videos; and an output module, configured tooutput the sub-videos to a corresponding display unit of an LED displayso as to display the sub-videos wherein the data processing devicefurther comprises: a low voltage differential interface, wherein the lowvoltage differential interface is configured to transmit the first videosignal is transmitted, wherein the low voltage differential interface isfurther configured to divide the first video signal into a first lowvoltage differential video stream and a second low voltage differentialvideo stream according to the resolution of a video, and transmit thefirst low voltage differential video stream and the second low voltagedifferential video stream, wherein the first low voltage differentialvideo stream comprises two differential data streams.